Symbol-printing mechanism



Jan. 5 1954 Filed June 29, 1950 N. R. FRIEBERG ETAL SYMBOL-PRINTING MECHANISM 14 Sheets-sheaf 1 NELSON R. FRIEBERG 8x OSCAR F. LARSEN THEIR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG ETAL 2,665,063

SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet 2 NELSONR FRIEBERG a OSCAR F LARSEN INVENTORS THEIR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG ETAL SYMBOL-PRINTING MECHANISM 14 Sheets-Sheet 3 Filed June 29, 1950 mNm NELSON R. FRIEBERG 8 OSCAR F. LARSEN mm 0% m QM I- THEIR ATTOR NEYS Jan. 5, 1954 N. R. FRIEBERG EIAL SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet 4 NELSON R. FRiEBERG a OSCAR F. LARSEN INVENTORS THElR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG EI'AL 2,655,063 SYMBOL-PRINTING MECHANISM Filed June 29, 1950 l4 Sheets-Sheet 6 FIG.8

NELSON R. FRIEBERG 8 OSCAR F. LARSEN INVENTORS wwm jLmA/ z THEIR ATTORNEYS 1954 N. R. FRIEBERG ETA]; I 2,665,063

SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet 7 whm 'llllllllllll ll Illlllll M llllllllllm IIIIIIIIIII SIIIIIIIIIII IIIIIIIIII! THEIR ATTORNEYS Jan. 5, 1954 Filed June 29, 1950 N. R. FRIEBERG ETAL SYMBOL-PRINTING MECHANISM 14 Sheets-Sheet 8 NELSON R. FRIEBERG 8 OSCAR F. LARSEN INVENTORS THEIR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG ETAL SYMBOL-PRINTING MECHANISM l4 Sheets-Sheet -9 Filed June 29, 1950 NELSON R. FRIEBERG 8 OSCAR F LARSEN INVENTORS BY %AL THEIR ATTORNEYS FIG. 24

Jan. 5, 1954 N. R. FRIEBERG EIAL I 2,565,063

SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet lo FIG. 37 I 70\ FIG. 56 g I FIG. 38

NELSON R. FRIEBERG 84 OSCAR F. LARSEN INVENTORS THEIR ATTORNEYS 1954 N. R. FRIEBERG ETAL 2,565,063

SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet 11 FIG. 27

429 NELSON R. FRIEBERG a OSCAR F. LARSEN INVENTORS C THEIR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG ETAL 2,655,053

SYMBOL-PRINTING MECHANISM Filed June 29, 1950 14 Sheets-Sheet l2 NELSON R. FRIEBERG 8 OSCAR E LARSEN INVENTORS THE"? ATTORNEYS W y bs;

Jan. 5, 1954 N. R. FRIEBERG ETAL SYMBOL-PRINTING MECHANISM 14 Sheets-Sheet 13 Filed June 29, 1950 I :2... 2 3 mwfiw 7 7 n77 F FIG. 33

744 NELSON R. FRIEBERG a OSCAR F. LARSEN INVENTORS THEIR ATTORNEYS Jan. 5, 1954 N. R. FRIEBERG EI'AL SYMBOL-PRINTING MECHANISM Fild June 29, 1950 FIG. 4|

14 Sheets-Sheet 14 NELSON R. FRIEBERG 8 OSCAR F. LARSEN lNVENTORS THEIR ATTORNEYS Patented Jan. 5, 1954 SYMBOL-PRIN TIN G MECHANISM Nelson R. Frieberg and Oscar F. Larsen, Ithaca, N. Y., assignors to The National Cash Register Ohio, a corporation of Company, Dayton, Maryland Application June 29, 1950, Serial No. 171,119

17 Claims. (01. 23560.17)

This invention relates to a calculating machine and more particularly pertains to symbol printing and operation control mechanism for a machine capable of receiving items additively or subtractively, with provision for printing true positive or negative totals or sub-totals.

The machine is fully automatic in that a total key is provided which, when operated, causes the true total to be printed, with an appropriate symbol, without any other action being required of the operator, whether the total be positive or negative. The same is true of a sub-total key which only has to be operated to cause the true sub-total to be printed, be it positive or negative.

The differential mechanism includes stop bars, differential racks, and printer setting mechanism of the basic construction shown in the Heber C. Peters United States Patent No. 1,386,021.

The transfer mechanism is a modified novel form of that shown in the above-mentioned Peters patent, being adapted for subtract operations.

The digit keyboard is substantially like that disclosed in the Charles Schroder United States Patent No. 2,062,731.

Novel mechanism is provided for automatically controlling the taking of a total, be it positive or negative, by operation of a single total control key.

Symbol-printing mechanism of novel construction has been provided for printing a clear symbol on the fi st item entry following a total if it be an add entry, even if preceded by a nonadd operation.

Another object of the invention is to provide other novel mechanism for setting operation designating symbol type to a printing position.

Novel means is provided to print zeros in the units and tens orders on total-taking operations when the totaiizer is already at zero.

With these and incidental objects in View, the invention includes certain novel featuers of construction and combinations of parts, a preferred form or embodiment of which is hereinafter described with ref rence to the drawings which accompany and form a part of this specification.

(if the drawings:

l is a perspective view of the machine with the casing on;

Fig. 2 is a vertical section, through a typical denominational order of the machine, from front to rear, showing the digit keyboard and the differential, totalizer, and printing mechamsms;

Fig. 3 is a view of the right side frame and the control mechanism on the outside thereof;

Fig. 4 shows more of the right side control mechanism, most of which is on the inside of the right side frame;

Fig. 5 is a view of the left side frame of the machine showing, especially, the motor drive, totalizer shifting, fugitive one control mechanism, and the paper feed mechanism;

Fig. 6 is a View of the control key bank secured to the right inside wall of the casing as viewed from the inside;

Fig. '7 is a top plan view of the machine tripping linkage across the under side of the machine;

Fig. 8 is a view of the right side mechanism for giving the platen an extra paper feeding movement on total-taking operations;

Fig. 9 shows the mechanism for holding the differential racks from movement during the first cycle of a total-taking operation;

Figs. 10 and 11 show the anti-rebound mechanism of a typical differential rack;

Fig. 12 is a plan view of the totalizer wheels and frame, and their relation to the differential racks;

Figs. 13 and 14 show, respectively, the subtracting and adding positions of the totalizer elements of a typical denominational order with respect to the associated differential racks and transfer levers;

Fig. 15 is a right end view of the mechanism by which the totalizer wheels are held immobile while out of mesh with the differential Figs. 16 and 17 show part of the i*ibbon-sn1fting mechanism as viewed from the right side;

Fig. 18 shows the train of mechanism for causing a subtract operation;

Fig. 19 is a detail of the fugitive one entry control mechanism after a subtract operation and just prior to the totalizer passing from a positive condition to a negative condition;

Fig. 20 shows the substance of Fig. 19 with an added showing of the indicator drum and the totalizer add and subtract pinions, with the fugitive one control mechanism as it is after an addition has been made to a positive total;

Fig. 21 shows a typical totalizer wheel with pinion and transfer pawl teeth;

Fig. 22 shows the substance of Fig. 19 when a negative total has been taken from the totalizer;

Fig. 23 shows a partly exploded view of the mechanism by which the selective shifting of the totalizer is effected in total-taking operations TECKS;

under control or the negative or positive condition of the totalizer;

Fig. 2 2 is a broken and partly exploded view of a typical differential rack and the means for entering the fugitive one in the units order under control of the highest order transfer latch;

Fig. is a diagrammatic showing of the Zero printing control. mechanism;

Fig. 26 is a diagrammatic showing of the relative position of the transfer pawl teeth, number drum, sight aperture, and transferleverassociated with the totalizer pinion of a typical denominational order;

Fig. 27 is a view of part of thetotalizer engaging mechanism and the associated totaletaking controls therefor, as seen from the right;

Fig. 28 shows the sub-total key mechanism and its relation to the substance of Fig. 27;

Fig. 29 shows part of the mechanism of Fig.28 at the middle of the second cycle of a sub-total operation;

Fig. 30 is a view of the add and total control keys with relation-to the machine release mech anism;

Fig. 31 is a view of the non-add operation control mechanism;

Fig. 32 shows the mechanism for setting the symbol-printing typebar in accordance with the type of machine operation;

Fi 33 is a detail of the ribbon frame and the linkage whereby its. movement in negative entry operations or negative total operations controls the symbol-printing type bar position;

Fig. 34 shows the substance of Fig. 33 moved from a positive position to a negative position;

. Fig. 35 is a detail of a portion of the substance of Fig. 32 as positioned in sub-total operations;

Fig. 36 shows the mechanism for controlling the symbol-printing type bar hammer;

Fig. 3'7 is a portion of the substance or .38 in moved position during a total-taking operation;

Fig. 38 is a detail of the setting mechanism of Fig. 37 at the end of a total-taking operation;

Fig. 39 is a detail View of how the symbolprinting hammer latch mechanism is coupled to the units order printing hammer latch;

Fig. 40 is an exploded view of the latch mechanism for controlling the tripping of the machine on non-add operations and for controlling the two machine cycles oi total and sub-total operations; and

Fig. ii is a top plan view of the printer and adjoining portions of the machine, with certain parts omitted.

General description The machine is housed in a casing 22 (Fig. 1) having a viewing aperture 2i covered by glass through which number wheels attached to the totalizer pinions may be seen. There are ten denominational orders of digit-representing keys 22 pro ecting through a dust plate 23 in the casing. Items to be added or subtracted are set up on the keyboard and the machine is set in operation by pressing the add control key 2e, if an add operation is desired, or by pressing the subtract control key 25, if a subtract operation is desired. A totalwaking operation is initiated by depressing total control key 2'3. If a sub-total operation is desired key 28 is depressed. Key 28 is a nonadd control, depression of: which causes the printing of any number set up on the keyboard but does not enter it into the totalizer. Key 23 is a correction control used to release any depressed digit keys. A set oi type bars 36 prints items, totals and symbols on a tape 3i held in a paper carriage 32. Lever is adjusted to singlespace, double-space or total-space position to control the extent of paper feed.

The machine automatically takes and prints true negative totals as well as positive totals, has a distinctive mark printed after the first entered item after a total has been taken, prints negative entries, negative sub-totals and negative totals in a distinctive color, red, and has appropriate symbols following totals, sub-totals and negative entries, negative sub-totals and negative totals.

The casing is secured to the machine framework by screws 34.

Machine drive The machine drive, including the motor, motor switch, tripping mechanism and single revolution clutch mechanism is substantially the same as that disclosed in United States Patent No. 2,428,084 which issued on the application of Harry L. Lambert.

The motor starting switch tripping mechanism is not shown in full detail herein, but sufficient is given for an understanding of the invention. For further details reference may be had to the Lambert patent.

The machine is driven through one cycle of operation on add or subtract operations and through two cycles of operation on total taking or sub-total taking operations. One cycle consists of the rocking of shaft 55 (Fig. 5) first clockwise then counter-clockwise by motor In two cycle operations the motor switch is kept closed during the reset movement of the motor swi h controls at the end of the first cycle, wi... be ex plained.

Whenthe motor switch is tripped it is accompanied by the counter-clockwise turning of shaft 35, and three-armed lever secured thereto, through the action of spring 38 anchored to the lever 3'! by stud id and to the machine framework by stud 39 on plate secure to left vertical side frame plate '22 by screws ll, 52 and 53. The relatching of the motor switch must be against the tension of spring 38. As the motor runs it turns shaft d5 counter-clockwise through reduction gearing. Shaft 35 has a notched drive wheel a secured thereto behind'crank plate loosely mounted on the shaft. Drive pawl ll pivoted on plate it by stud so is urged in an engaging direction toward the notched drive wheel by spring :39 anchored to the pawl and to stud 5% on plate 45 but is disengaged therefrom when the machine comes to rest by r ason of stud 6t bearing against surface 83 on the rearwardly extending arm of pawl il. However, as soon as lever 37 rocks counter-clockwise the motor starts, pawl ti is released engages the notched drive wheel 55a, rotating crank plate 45 counter-clockwise. Shaft has loosely mounted thereon a crank 5e connected to plate 35 by stud 5!, connecting link 52 and stud 53. Crank is coupled to the main drive shaft 55 by a yielding driving connection including lever 55, pivoted on stud 53, and a roller 5'? mounted on the outer end of the lever. The roller is urged by a strong spring 58 into a notch 52 in the edge of a plate 69 secured to shaft 5 5. Spring is strong enough to hold roller 5'? in the notch to form a driving connection between crank 5d and shaft 55 during all normal operations of the machine. The driving connection will yield, however, to

any overload placed on the main drive shaft. As crank lever 46 is about to complete a rotation, a cam arm iii secured thereto strikes roller stud 62 on lever 3? rocking it clockwise to normal position in which position it is latched in single cycle operations. As crank lever 46 nears home position pawl 4? is rocked clockwise on stud 48 as surface 53 strikes stud 64. On two cycle operations lever 3? is not latched in normal position at the end of one cycle as it is knocked. clockwise by arm 6| but immediately returns to its counter-clockwise position before it has a chance to disengage pawl ll. On two cycle operations the lever 31' is latched in normal position after two cycles of operation. Whenever lever moves to and is latched in normal position the motor switch contacts are opened permitting the rotor thereof to coast to a stop disconnected from crank lever 46.

Fig. '7, in part, shows the control linkage by which lever t'l is unlatohed and held unlatched for one or two machine cycles under control of mechanism on the right side of the machine. Lever 62a pivoted on vertical stud 63a on a frame member on the under side of the machine engages unlatching member 63?) when lever 82a is rocked counter-clockwise slightly through movement of link 65 in the direction of the arrow. That movement of link 65 is brought about through a pivot connection 64 to the bent-over end 65 of one arm 6? (Fig. 3) of a bell crank lever 68 pivotally mounted on screw stud 555 mounted in a boss 19a (Fig. 4) extending outwardly from the right side vertical frame plate ill of the machine. Rocking crank lever 63 slightly clockwise from the normal position shown in Fig. 3, against the counter-urge of spring ll will set the machine to cycling and it will continue to do so until crank lever 68 is returned to normal position.

On add operations lever I93 is rocked down and stud l 06 in turn rocks bell crank lever lfi'i mounted on stud 493 clockwise carrying with it lever 58 to which it is coupled by spring m8.

Referring again to Fig. 3, the drive shaft 55 extends across the rear end of the machine and in one machine cycle rocks first counter-clockwise and then clockwise to actuate the differ ential, control mechanis and printer.

The dz'fierenticl Secured between the front end of the right vertical side plate it (Figs. 3 and 4) and front end of the left vertical side frame plate l2 (Figs. 2 and 5) is a slotted. plate or comb l3 (Figs. 2 and 5) in which the front ends of a series of denominational order stop bars are guided and suppored for sliding motion. There is one stop bar for each denominational order. As the stop bars of all orders are constructed the same, a typical order only is shown in Fig. 2, as an example. Stop bar i is pivoted at the rear end by stud l5 to the upper extending arm of a threearmed diverging lever '35 pivotally mounted on shaft iii, and is normally urged forwardly by spring is stretched between a stud l9 and comb 73. The stop bar normally is held against forward movement by a bail 56. extending across the front of all the diverging levers and held between two arms pinned to shaft Tl. The right arm 8i (Fig. 4) has a downwardly extending arm pivoted to a link 82 having rotatably mounted thereon a roller 53 which is held in engagement with the edge of a cam 84 pinned to drive shaft 55. The rear end of link 82 has a forked end 85 which embraces and rides shaft 55 for support. As shaft 55 rocks counter-clockwise shaft 11 will do likewise causing a forward. and down ward movement of bail 30 by reason of the urge given by the springs, like spring '53 (Fig. 2), ing ing the stop bars forward. On return movement of the bail B3, on the clockwise movement of shaft 55, the stop bars will be returned to the rest position of Fig. 2. A rearwardly extending arm of lever 16 is pivoted to one of a U- shaped adjusting link 86 the other arm of which is pivoted on a stud 81 of a printer arm #38 where it is retained by a spring clip 82. Printer bar 8b is adjusted vertically in slotted guides and 9! with respect to the paper platen 532, shown diagrammatically, according to the selective positioning of three-armed diverging lever l6 under control of the digit keys to be described. Printer bar 88 has at the top end ten vertically spaced type 93 movable, individually, in a case 9 from the shown position toward the paper platen. The type are urged to the retracted position, shown, by springs within case the par ticular type at printing position is hit by printing hammer 95 when released from the cooked position, at printing time, by the tri ping of a latch 95a. When a type bar is se1ec="vely raised to printing position an interponent 96 rocks counter-clockwise on bail Eil under urge of spring 93a. Bail 3'! is secured between arm pivoted on shaft 93 and another arm like also pivoted on shaft 99. Bail 9? extends across the printer. Cain lever lilii on shaft is rocked counter-clockwise and then clockwise during a machine operation and. stud idi thereon strikes the tail I82 on arm 93 rocking the interponent toward latch 95a whi h is unlatched at mid-cycle, if the type bar has been 1r. .ed from home position, causing the printing hanimer 95 to hit the type at the pri- The described printing mechanism is duplicated in each denominational order except that the rearwardly extending arms of the three-armed diverging levers like lever it, order connect to the associated type bars, which are crowded together as'shown in Fig. 1 instead of being in line with the respective keybank denc: are bent according to the relative lat l osition between a stop bar and its e bar.

Means, to be described, is provided for printing zeros, to the right of the first sign di it in those columns in which a di it i not been depressed, and to print zeros in and tens orders on total-tak g operation the totalizer is clear at that 'r e.

The printing mechanism so described s old, being described in the Peters Un .ed States ent 1,386,021 to which attention as bee rected. The rear lower end of typ has a series of notches i2 3 be on by a bail 21, on totahtaking operations printing and before disengagement the totalizer from the (inferential, to s "'"-ming of the differential to full operated co: such mechanism does not constitute a t invention the operating and timing mechanism for this bar has not been shown.

A forwardly projecting arm 522 of lever 16 has mounted thereon alining I23 the ten teeth of which pass front u an alining bail I24, serving all denominational orders, which is rocked toward the rack dur ing the middle part of the machine cycle dur ing totalizer eng ing time to hold t e rigidly in set position. Alining i it. u. in a rockable frame including two side arms, the

left one of which i255 is shown, and a bail support rod iZS connecting said side arms. The side arms are pivotally mounted on studs mounted on the inside of the vertical side plates it and ii. The alining bar assembly is rocked by cam 26d secured on cross shaft its iournaled in side plates Hi and "i2 and rocked counter-ciockwise and then clockwise by drive shaft (Fig. 3) through plate ESE, pivot E52, link E33, pivot 53d and plate i35 pinned thereto. Returning to Fig. 2, scissor arms m6 and is? pivotally mounted on cross bar E26 have studs E33 and E39, respectively, which are kept in contact with the edge of cam Etta by spring Hit. The alining bar set into scissor arm 53% which, when rocked, rocks the alining bar assembly. Cam iZta is so formed as to bring the alining bar into the rack shortly before mid-cycle. As the totalizer comes into engagement with the differential racks on the diverging levers, to described, just before midcycle in item entering operations, the alining bar holds the racks in perfect adjustment insuring proper meshing of the teeth.

On the side of stop it is an adjustable stop plate M the forward end of which strikes comb it to limit the forward movement of the stop bar. Referring to Fig. 9, stop plate id! is engaged by bail Hi2, during the first cycle of total-taking operations, to hold the differential from movement, as will he described later.

Referring to Figs. and 11, there is a plate Hi3, secured to the stop bar it, the lower edge of which has teeth i i-l3 adapted to be engaged by pawl Hi5 which is raised thereagainst during the forward movement of the rack to prevent any rebound of the rack when it is suddenly halted by a key. Pawl M5 is rotatably mounted on shaft M 5 extending between the vertical side frame plates and is held in a slot in a comblike bail Isl extending across the machine. Bail M?! has two rearwardly extending arms between which is mounted a rod M8 to which is anchored a spring M9 whose other end is secured to a rearwardly extending arm of pawl i 35. Thus the pawl and ball move together except that the pawl may rock counter-clockwise against the urge of spring M9. The assembly of pawl I45 and bail Ml normally is in the position shown in Fig. 11, as urged by spring its secured to the base of the machine. Pivoted to arm 55! of the ball is a link 5522 having at its rear end an elongated slot through which passes a rod 553 extending from the left side plate i2. Pivoted to side plate ?2 is a bell crank lever ESQ having an offset in its upwardly extending arm L55 which is held against the upper edge of link I52 by spring 256. Movement of link I52 rearwardly allows the offset of arm 355 to drop into a looking notch which holds the link in rearward position until bell crank 554 is rocked counter-clockwise. Pinned to rock shaft 23% is a lever l5? having a normal position as shown in Fig. 11 and a moved position, as shown in Fig. 10, at mid-cycle. As shaft H36 rocks counter-clock wise during the first half of a machine cycle it strikes stud H58 moving link I52 rearwardly where it is latched by bell crank id l at mid-cycle, holding pawl i i-5 out of contact with stop bar it so that stop bar may return to home position. During the first half cycle of machine operation pawl 8 55 has been clicking over teeth [55 to prevent a possible rebound of the stop bar. As lever :5! moves clockwise during the last half of the machine cycle it approaches and finally strikes stud ltd on bell crank lever 55 t, rocking it counter-clockwise, unlatching link 552 so it is returned to the position of Fig. 11. All the stop bars are controlled by the bail EM and associated mechanism.

The digit keyboard The keyboard in which the digit keys for controlling the movement of the differentials are mounted has a main frame including a top plate H5 (Fig. 2), a bottom plate lit, a left side plate I'll, and a right side plate H3 (see Fig. 5).

A typical denominational keybank column is shown in Fig. 2. The keys 5% have key stems slidably mounted in alined slots cut in the top and bottom plates and are normally held up in ineffective position by springs such as spring H9. Any depressed key has its key stem projecting below bottom plate H6 and is adapted to be struck by an associated one of teeth on stop bar M as it moves forward on the first half of an entry machine cycle. The extent of movement of stop bar it is proportional to the digit value of the key depressed. Each keybank has a zero stop bail E82 and a latching bail lti. When a key in the bank is depressed bail I82 is rocked to move a zero stop member I83 from a position in which it blocks any significant movement of the stop bar except that sufficient to move the type bar to zero printing position. Bail liii latches any depressed key in depressed condition until unlatched by a rocking of bail it; by depression of another key in the bank or by rocking of the key release bail its as stud 88% (Figs. 3 and i) is struck downwardly by bypass pawl E55 (Fig. 3). By-pass pawl 58% is pivoted on lever i871 which is rocked clockwise on pivot 232, during the first half of a machine cycle, when pawl H85 by-passes stud i855, and counter clockwise, during the second half of a machine cycle, when pawl I86 knocks stud its downwardly releasing the keys. Spring 583a normal ly urges lever 58? clockwise and its rocking excursion clockwise from the home position is permitted when roller stud Hill is moved from under its rearwardly and downwardly extending leg Hill. Stud N39 is on plate E35, before described, and rocks back to home position, shown, at the end of a machine cycle at which time the keys are released, except on repeat operations wherein repeat lever i9! is rocked clockwise. the normal position of repeat lever iti stud it?. on lever i8? is free to move upwardly into notch 93 in lever is! thus giving said lever it? sufficient movement so by-pass pawl E85 passes stud 585. If lever 19! is rocked clockwise stud its on retaining pawl I normally in engagement in a front notch of lever l8! engages the rear notch i83 thereof, at which position edge Hit of lever l9! blocks movement of stud iSE and conse quently the key release actuating lever is? is not rocked by spring 38a. A locking bar 593 extends across the rear ends of all the keybanks and is resiliently urged toward the right such movement locking the digit keys from movement whether in depressed position or not, and such outward movement occurs when the tail on key release actuating lever is? moves from home position at the beginning of a machine oper ation. Return movement of lever it? at the end of a machine operation forces locking bar 13% to inward position to permit selective depression of the digit keys for the next operation. In repeat operations there is suflicient clearance be tween edge I95 of lever i9! and stud W2 to per mit lever H3! to rock clockwise a sufficient amount to lock the keys. To insure key locking bar I98 has functioned properly, a three-armed interlock lever 286 pivoted on stud 26| is urged counter-clockwise by a spring 262 acting on a rearwardly extending one of the three arms to hold a downwardly and forwardly extending arm against stud H35 in plate i35. In the home posi tion of plate I35 the forward and upwardly extending arm 253 is above locking bar 198, but as soon as plate I35 rocks counter-clockwise in the first half of a machine cycle stud 89 becomes ineffective and allows arm 253 to drop toward locking bar $58 which is then moving outwardly as lever l8? rocks clockwise. Arm 263 continuing movement enters a notch in extended locking bar I98 to hold it in looking position during the remainder of the machine operation until stud I89 comes to home position. In the event locking bar I88 fails to move outwardly arm 263 does not complete its movement and the machine action is blocked by toe 224 hitting a formation 205 on a stop plate secured to the inside surface of plate I35. The action of arm 2G3 occurs every cycle of operation so a key cannot be depressed during a movement of the stop bars.

A manually operated key release is provided for releasing any depressed key except during a machine cycle and between cycles of a two-cycle operation. Correction key 29 (Fig. 6) slidably mounted inside the machine casing in alined slots in bent-over ears of bracket 225 normally is kept in the up position by spring 223 but may be depressed against its restoring action. A rearwardly extending arm thereof has a bentover ear 22'! which, when the casing is on the machine, is directly above a flattened surface on a stud 228 (Fig. 3) projecting from the front end of a lever 229 pivoted on screw stud 235. Counter-clockwise rocking of lever 229 by key 2?; causes surface 23! thereof to strike stud I85 rocking bail we thus releasing the digit keys. Lever 229 normally is held with a surface on a rearwardly extending arm thereof resting on screw stud 232 by means of a spring, not shown. Rocking of lever 68 clockwise upon release of the machine for motor operation places arm 233 thereof under stud 228 preventing key-release movement of lever 229. Bent-over hook 234 on lever engages surfaces on the rearwardly extending arm of release lever 22% to prevent its movement when the machine is operated by a crank rocking shaft 136 without rocking of motor release lever 68.

Reference is made to United States patent to $chroder 2,062,731 and to United States patent to Lambert 2,389,062 for a more detailed description of the digit key bank construction, the description given herein being sufiicicnt for an understanding of the invention.

The totalizer Referring to Fig. 12, the totalizer is mounted in a frame including a shaft 250 journaled in bearings 25i and 252 mounted respectively in side frame plates 12 and Hi, a left support arm 253, a right support arm 254, intermediate support arms 255, 255, 25?, 258, 259, 260, 26!, 262 and 263, and a shaft 264 extending between the rearwardly extending ends of sup-port arms 253 and 254 and passing through support arms 255 to 263. The totalizer wheels are rotatably mounted in spaced relation on shaft 264. Each totalizer wheel (Fig. 21) has a ten-toothed pinion 265 to which is attached an indicator drum 266 bearing on its periphery ten digit numerals spaced according to the associated teeth of the pinion. On the left side of each indicator drum is a transfer pawl member having a subtract tooth 257 used in subtracting and negative total operations and an add tooth spaced 36 therefrom with reference to the pinion circumference and spaced leftwardiy from tooth 267 as viewed from the front of the machine, said add tooth being used in add and positive total operations.

Referring to Fig. 13, shaft 253 is shiftable leftwardly from the adding position shown, wherein toothed racks on the differentials, to be described, are in alinement with the associated pinions on the totalizer wheels, to a subtracting position in which the racks are in alinement with teeth on intermediate or idler pinions.

Taking the tens order totalizer wheel as a specific example, its pinion 2T5 (Figs. 12, 13 and 14) is in alinement with the tens order differential rack 216 in the adding position of the totaiizer as shown in Figs. 12 and 14, whereas when the totalizer is shifted left to subtract position the rack 2N5 is in alinement with teeth 21! (Fig. 13) on idler pinion which has another set of teeth 275, spaced therefrom by coilar 280, which are in constant mesh with pinion 215.

A view of the three-armed diverging lever for a typical denominational order, and which will be discussed in connection with the tens order 'totaiizer wheel, is shown in Fig. The upwardly extending arm 28i has mounted thereon the toothed rack 2716, the mounting being of the stud and slot type which permits of relative movement of the rack forwardly, from the normal position shown in which it is neid by spring Abutment 284 extends laterally from rack 2h} and normally strikes an ear of a transrer lever rocked by the totalizer wheel or" next lower order as it passes through zero, which in the example under consideration is the units order, when such wheel approaches zero either in an adding or a subtracting direction. With the transfer lever in normal position, or return of three-armed lever '16 to home position in the last half of a machine cycle, the rack 2'16 is stopped by the ear one tooth step before lever l6 reaches home position. The movement of the rack toward home position with lever 26, with the transfer lever of next lower order blocking the rack, is proportional to the digit to be entered in accordance with the value of the depressed key. If the transfer lever is moved and latched in moved position, as wili be described, the rack gets an extra step of movement which represents the transfer of one unit from the next lower order.

In home position of the machine the totalizer pinions are in engagement with their respective racks and either the totalizer wheel pinions directly or through the idler pinions, depending on the lateral position of the totalizer frame unit as determined by the positioning of shaft 255 (Fig, 12) When the shaft is in the right position racks are engaged with the totaiizer wheel pinions and the collars between the sets of teeth on the idler pinions act as clearance slots ror the excursions of the racks. In the left position of shaft 258 the racks are engaged with the idler pinions.

As shown in Fig. 12, the idler pinions are mounted on studs on th support arms, idler pinion 218 of the tens bank, mounted on support arm 263, being typical.

The engagement and disengagement "f the totaiizer pinions with the racks is accom lished accaose 11 by rocking the frame consisting ofsupport arms 253 to 253 and shaft 264 about shaft 255'.

Right side support arm 254 (Figs. 12 and 2'7) has a downwardly extending arm 28% (Fig. 27) having-a roller studEBi engaged in a cam slot 238 in a lever 289. Fig. 2'7 shows the. position of the parts in home position with the totalizer pinions in engagement with the differential racks. If the totalizer engaging lever is rocked clockwise until stud 28? is in the other end of the slot 288, the arm 254 will be rocked counter-clockwise carrying the totalizer wheel pinions out of engagement with the differential racks. It is so arranged, as will be described in connection with the description of the totalizer engaging actuating mechanism, that the totalizeron item entering operations, either those of addition or subtraction, which require one machine cycle,

'is disengaged during the first .partof the first half cycle and re-engaged near the end of the first half cycle. During disengagement the totalizer may be shifted laterally and the stop bars and differential racks set to the selected positions. Other things such as transfer reset and printing occur during the totalizerdisengagement. The totalizer is reengaged with the racks beforethe second half of the machine cycle commences and durin the second half cycle the selected digit values are entered into the totalizer.

To keep the totalizer pinions from moving While out of engagement with the racks, there is a pawl Ede (see Figs. 12 and 15) associated with each pinion. Pawls 24s are a part of plate 241 adjustably mounted on a bail 242 having bifurcated end portions embracing shaft 25!! on which it is rockable and held by spring M3 (Fig. 15) rocked clockwise until extension 2Mv (Fig. 12) strikes side frame plate 12 as the totalizer moves toward engagement with the racks, lifting the pawls 242 from engagement with the totalizer pinions. As the totalizer pinions are disengaged from the racks the pawls 24c become engaged therewith to hold the set position.

SeZection of totalizer for addition or subtraction Assuming the totalizer is in add position and it is desired to condition the machine for subtracting, depression of the subtract key 25 (Figs. 1, 6 and 18) slidably mounted on studs 288a and 289a mounted on bracket 225 mounted on the right inside wall of the casing, against the restoring urge of a spring 2%, brings the lower edge of arm 29f into engagement with stud 292 (Fig. 18) of plate 293, mounted on screw stud 232 (Fig. 3), rocking it clockwise, causing stud 294 resting in a fork of lever 295 to rock lever 295 counterclockwise turning shaft 296, to which it is pinned, in the same direction. Shaft 2% extending across the machine and journaled in side frames it and 172 has secured to its left end a lever 29? (see also Fig. having a stud 298 riding in a slot in the forward end of a link 299 equipped with a stud see riding in a slot in lever 30f the upper end of which is pivotally connected to stud 302 on totalizer shifting cam 383 which is mounted on side frame-held stud 303a and which has a curved slot 356 (see Fig. 23) in which rides roller stud 355 (Figs. 5, 12 and 18) secured to the end of totalizer shaft 2%. Depression of the subtract key 25 rocks lever 3%], as seen inFig. 5, counter-clockwise. On the left end of rock shaft use (Fig. 5) is a plate 306 which'rocks clockwise and then. counter-clockwise during a machine cycle. With the machine having the parts in the position shown in Fig. 5 plate 3136 accomplishes nothing during a machine cycle. If the subtract key is depressed, lever 361i is rocked. counter-clockwise and, when a machine cycle commences stud (iii? engages surface 3&8 pulling lever 30! down, rocking cam 303 counter-clockwise shifting shaft 250 to the left to bring the totalizer into subtract position with the idler pinions in line with the differential racks. This shifting occurs just after the totalizer pinions are disengaged from the racks. To insure continued depression of the subtract key during the-machine cycle, a hook 369 (Fig. 6) moves over a stud Sid on the stem of subtract key 25 as it is pressed down. Hook 309 is part of and extends upward from a link 3! I mounted by stud and slot coupling to the bracket 225 on the inside of the casing, for forward and backward movement, and is moved into effective position by spring 3 i2 when a tail hooking over stud M3 on lever 3H3 is released. Lever Sld (Fig. 3) is pivoted to the side frame 10 and is urged counter-clockwise against stud 315 on link 5323. As link 33 moves forward on a machine cycle in response to the urge of spring 316, the hook 309 (Fig. 6) moves toward stud 318 striking it if the subtract key is not depress-ed, but locking it in depressed position if it had been and is being held depressed by the operator until the machine cycle starts. 0n the second half cycle of the machine the key is unlatched as stud 3l5 strikes lever Sid.

If the next machine operation is a subtract operation lever 36! being rocked by link 299 (Fig. 5) remains in its down position. If the next machine operation is an addition operation stud 316a will strike surface 3!? of lever Edi kicking it up to add position, as link 299 will not have been pulled forward, under which latter circumstance stud 316a would have moved along the rear edge of lever 30L Transfer mechanism Referring to Fig. 21, it will be remembered that on each totalizer wheel there is a transfer pawl tooth 268 that is associated with adding operations and positive total-taking operations. Similarly tooth 261 is associated with subtracting operations and negative total-taking operations.

Associated with each totalizer wheel adjacent its left side is a transfer lever, a typical lever 3255, representing the units order, being shown in Fig. 24, rockably mounted on a shaft 32! supported by the machine framework.

This transfer lever has an outer offset portion 322 (see also Figs. 13 and 1 in line with the add tooth of the transfer pawl (see toc-th 253, Fig. 21) of units order when the totalizer is in add position. On adding operations, as the add tooth of the totalizer pinion approaches zero position it rides on cam surface 323 (see also Fig. 2) rocking the transfer lever down where it is latched by ear 32s (see-also Fig. 2) of a latch member, entering notch Ear 326 is thereby taken out of alinement with the abutment on the differential rack of the tens order, allowing an additional movement of one unit to the totalizer wheel of next highest order in the manner heretofore described. On total-taking operations, where a positive total is involved vertical stop surface 3210f the offset portion'of transfer lever 32c engaging the add tooth stops the associated totalizer wheel when it reaches zero position in its total-taking reverse rotary movement. Similarly, when the .totalizer is shifted to the left for subtraction or the taking of negative totals, per- 

